Resistance Method

ABSTRACT

The Resistance Method is a process for the conditioning of an electric current to subject it to manipulated resistance levels to cause a effect on the solution or substance as the current passes through. The method has two basic functions. One is to condition the electric current. This takes place during the series of steps that manipulate the frequency, voltage, and amps to provide a combination suitable to your setpoints. The other is to manipulate the resistance of a solution or substance. This is done by manipulating the atmospheric pressure, ph, salinity, and temperature of the solution of substance. This all takes place in a reactor. The reactor provides a isolated enclosed environment for the reactions to take place. The method also utilizes an electronic control system. The electronic control system simultaneously measures and manipulates the variables of the process, thereby creating an environment in the reactor that either increases or decreases the amount of resistance the electric current is subjected to.

BACKGROUND OF INVENTION 1. Field of the Invention

The Resistance Method is truly a novelty. With that being said I am going to take this opportunity to give you the background of how this method came about. It all started with electrolysis. I wanted to use the hydrogen to heat my family's tobacco barns. I had come up with a method of wiring the reactors together that I thought could make the process more efficient. While running test I noticed that the process was producing a lot of heat. The same heat that I was going to burn the hydrogen to make in the first place. Through my research I came to the conclusion that this was caused by electrical resistance in the solution as the electrical current was passing through. I began to come up with ways to manipulate that resistance and so was born my method.

BRIEF SUMMARY OF INVENTION

The general purpose of the present invention which will be subsequently described in greater detail is to provide a method for conditioning of an electric current to subject it to manipulated resistance levels to cause an effect on the solution or substance. Electrical resistance causes heat that is generated as the electrical current passes through a solution or substance. This method is designed to create an environment in the reactor that either increases or decreases the

amount of resistance the electrical current is subjected to. By increasing the resistance you can create hot water and steam and by decreasing the resistance you can create an environment with better conductive properties.

To attain this, the present method generally comprises of a reactor that Isolates the interior reactions from the external environment. It should be able to withstand the temperatures and pressures that you wish to exert on the substance or solution. The way the reactors are wired together aid the process and increases the overall efficiency. This is part of what we call the wiring method. The placement of your cathode and anode aid the process but can vary in configuration depending on setup. The method also utilizes a Electronic Control System designed to simultaneously measure and manipulate the variables of the process. Other components are a pump

to circulate the solution between the reactors, and a pump to add solutions as needed. There has thus been outlined rather broadly the more important features of the method in order that the detailed description thereof may be better understood. There are additional features of the invention that will be described hereafter and that will form the subject matter of the claims appended hereto.

In that respect before explaining at least one embodiment of the invention in detail, It is understood that the invention is not limited in its application to the details of the construction or arrangement of the components set forth in the following description or illustrated in the drawings. The invention is capable of other embodiments and of being practiced and carried out in various ways. Also it is understood that the phraseology and terminology employed herein are for the purpose of the description and should not be regarded as limiting.

A primary object of the present invention is to use the reactor, computer system, and the other steps of this method to make steam for power generation.

A second object is to use the reactor, computer system, and the other steps of this method to heat water.

A further object is to use the reactor, the computer system, and the other steps of this method to achieve a higher level of conductivity.

To the accomplishment of the above and related objects, this method may be embodied in the full form illustrated in the accompanying drawings, attention being called to the fact however, that the drawings are illustrative only and that changes may be made in the specific construction illustrated and described within the scope of the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

Various other objects features and attendant advantages of the present invention will become fully appreciated as the same becomes better understood when considered in conjunction with the accompanying drawings in which like reference characters designate the same or similar parts throughout the several views and wherein.

FIG. 1 is a schematic illustration of the wiring of a single reactor

FIG. 2 is a schematic illustration of the wiring of multiple reactors

FIG. 3 is a schematic illustration of the programmable logic controller

FIG. 4 is a schematic illustration of the programmable logic controller

FIG. 5 is a flowchart illustrating the activation and operation of the present invention

FIG. 6 is a illustration of the top view of the reactor

FIG. 7 is a illustration of the side view of the reactor

DETAILED DESCRIPTION OF THE METHOD A. Overview

The Resistance Method is a method of conditioning the current and manipulating the resistance levels of an solution or substance and the electrical current to achieve a desired result. These results can vary from increasing the resistance to create hot water or steam to decreasing the resistance to achieve a higher level of conductivity. Any of these steps can be performed independently, in any combination, or simultaneously. The steps of the method are designed to increase the overall efficiency of the process.

B. Reactor

The reactor is comprised of having one internal compartment that provides a isolated enclosed environment for the reactions to take place. FIG. 6 shows a top view of the reactor. Items 26-33 represent the anode. Each one of these are jumpered together to distribute the intake of power from L2 of FIG. 2 Item 25 represents the cathode. Items 42 and 24 in FIG. 6 represent the in and out of the circulation system. It can be of any size or shape as long as it is suitable to subject the electrical current, solution, and or substances to the steps of this method. It must be insulated to prevent the bleeding of the electric current causing voltage lose. It must be able to withstand the temperature and pressure requirements. The cathode and anode placement is instrumental in the method in that they allow spark gap to take place. It must have suitable heat wells for taking temperature readings as pictured in 40 of FIG. 7. It must have a inlet and outlet for the solution to circulate through as pictured in 42 and 46 of FIG. 7. It must have a steam outlet valve as pictured in FIG. 7 item 24. It must have a well for taking ph as shown in pictured in 38 of FIG. 7. It must have a well for taking salinity as pictured in 48 of FIG. 7. It must have a gauge for measuring atmospheric pressure as shown in 35 of FIG. 7. It must have a well for a float switch as seen in FIG. 7,50

C. Wiring the Reactor

The electrical wiring of the reactors is illustrated in FIG. 2. It shows how the power is distributed from reactor to reactor. If you wire the reactor straight to neutral like shown in FIG. 1 The current is entering the reactor on L2 which represents the anode and leaving the reactor on the neutral which represents the cathode. Now lets say this reactor is using 25 amps. To add any additional reactors is going to cost you an additional 25 amps per reactor. This is not the case if the reactors are wire as shown in FIG. 2. In doing so you bring L2 in on the anode of the first reactor and out on the cathode the same as in FIG. 1. The difference being instead of taking it to the neutral you take it to the next reactors anode. This enables you to the same 25 amps to run multiple reactors. The wiring of the reactors assist in the conditioning of the electric current to subject it to the desired resistance levels to effect the substance as the current passes through.

part of the conditioning of the electric current to be applied to a substance. In addition operating multiple reactors at the cost of the same twenty five amps adds in the overall efficiency to the process.

D. Electronic Control System

The next step is to utilize a computer program, computer hardware, and peripherals to simultaneously measure and manipulate the variables of the process. These steps come together to form the Electronic Control System. For example a PLC can be used to take in information like temperature, reactor pressure, salinity, and current amperage as shown in FIG. 3 and FIG. 4. This information can then be used to determine which step of the method is better applied to achieve a specific result. The program is divided into sequences. Each sequence has a specific set point for that must be met in order for the program to advance to the next sequences as seen in FIG. 5,21. Once the program runs through the sequence the temperature is taken. If it meets the set point then the program moves on to the next sequence. If it is not met then the program continues to apply until the temperature set point is met. Once tuned in to you specification it can maintain your desired level of performance. The computer program, hardware, and peripherals assist in the conditioning of the electric current. It also aids in then subjecting the current to parameter driven resistance level as the current passes through the substance or solution.

E. Solution Pump

The solution pump as seen in FIG. 4, FIG. 1 and FIG. 5,36 is responsible for adding the solutions as need to the reaction to keep solution within the perameters of the setpoint. For example if the reaction needs for the resistance to be lowered the pump can add more salt water solution. If the resistance needs to be increased the solution pump can add fresh water.

F. Circulation Pump

The circulation pump as seen in FIG. 4, FIG. 1, and FIG. 5,34 is used when their is a need to circulate the solution inside the reactor. An example of this would be if the setpoint required you to make changes to the solution. The circulation pump would circulate those changes throughout the reactors.

G. Float Switch

The float switch as seen in FIG. 3 as well as in FIG. 7,50 is used to let the PLC know when the solution level in the reactor is getting low and additional solution needs to be added.

H. The Manipulation of Voltage

The next step is the manipulation of voltage. FIG. 4 shows the volt meter that constantly reads the voltage. The PLC can then keep the voltage set point seen in FIG. 5,14. This allows the system to regulate the voltage. Part of this step was hit on earlier in the anode cathode section in the discussion about spark gaping. Spark gapping is only one way of manipulating the voltage. You could also use an external capacitor or any other means of manipulating the voltage. By whatever means the manipulation of voltage assist in the conditioning of the electric current to subject it to the desired resistance levels to effect the substance as the current passes through.

I. Manipulation of Frequency

The manipulation of frequency is the next step. The manipulation of the frequency of the current is a current conditioning aspect of the method. The frequency meter in FIG. 4 keeps the PLC informed of the condition of your current. It can then be manipulated to maintain the frequency set point as shown in FIG. 5,16. The manipulation of frequency assist in the conditioning of the electric current to subject it to the desired resistance levels to effect the substances as the current passes through.

J. Manipulation of Amps

Next is the manipulation of amps. The manipulation of the amperage of a current is a current conditioning aspect of the method. By changing the amperage you can attain a desired level in a longer or shorter amount of time. This causes you to use more or less power. If you look at FIG. 2 you will note how the power enters one reactor and leaves to feed another. By placing an ammeter at each of these locations you can monitor the changes in your current from reactor to reactor. Please note the ammeter on FIG. 4 going to the input side of the controller. The computer system can then decide what needs to be done to keep a constant setpoint as noted on FIG. 5,13. The manipulation of amps assist in the conditioning of the electric current to subject it to the desired resistance levels to effect the median as the current passes through.

K. Manipulation of Salinity

The next steps cover conditioning the resistance properties of the substance being electrolysis. By manipulating a substance using these steps you alter its conductive abilities. The first of these steps is to manipulate the salinity of a substance. In doing so you change the conductive nature of the substance. If you look at FIG. 7,48 you see a salinity meter. It feeds the salinity into the PLC as seen in FIG. 4. Which then uses the information to maintain the salinity set point as seen in FIG. 5,18. An example of this is to decrease the salinity of water to increase its resistive properties to heat the water in slower yet more efficient manner. By the same token if you wanted to heat it faster you could increase the salinity to increase the amps of the current that is passing through the substance. The manipulation of salinity assist in the conditioning of the resistance of a substance to subject it to the conditioned current to effect the substance as the current passes through.

L. Manipulation of Temperature

The next step is the manipulation of the temperature of the substance. This step allows you to balance the heat build up in your substances that are being electrolysed to either increase or decrease conductivity. It starts with a temperature sensor in each reactor as shown in FIG. 7,40. From there it goes into the PLC as shown on FIG. 4. Where its feed into the program as shown on FIG. 5,20. Manipulating the temperature assist in the conditioning of the resistance of a substance to subject it to the conditioned current to effect the substance as the current passes through.

M. Manipulation of Atmospheric Pressure

The next step is manipulating the atmospheric pressure. This step effect both current conditioning as well as resistance. By increasing or decreasing the pressure of the reactor you can have an effect on the conductive properties of the substances being electrolysed as well as use it as a method for altering frequency. FIG. 7,35 shows a pressure sensor. That information is then feed into the PLC as seen in FIG. 4. The PLC then matches the reactor pressure with the pressure set point shown in FIG. 5,16. The manipulation of atmospheric pressure assist in the conditioning of the resistance of a substance to subject it to the conditioned current to effect the substance as the current passes through.

N. Manipulation of PH

The next step is the manipulation of the ph of a substance. The conductivity of a solution depends on the concentration of all the ions present. The greater the concentration the greater the conductivity. The manipulation of ph by adding substances to your solution that change the balance of cations to anions will give you another method of controlling the resistance of the solution. The reactor should have a well for a ph meter as seen in FIG. 7,38. Information from this sensor enters the PLC as shown in FIG. 4. The control system will keep your ph in line with the setpoint of your program for each stage of the sequence. FIG. 5,17 shows this portion of the program. If the solution is not meeting the setpoint the solution pump is activated also shown on FIG. 4. This manipulation assist in the conditioning of the electric current to subject it to the desired resistance levels to effect the substance as the current passes through.

With respect to the above description then, it is to be realized that the optimum dimensional relationships for the parts of the invention or the solutions of the invention, to include variations in size, materials, shape, form, function, and manner of operation, assembly and use are deemed to be within the expertise of those skilled in the art, and all equivalent structural variations and relationships to those illustrated in the drawings and described in the specifications are intended to be encompassed by the present invention.

Therefore the foregoing is considered as illustrative of the principle of the invention. Further since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to its exact construction and operation shown and described and accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the invention. 

1. (canceled)
 2. The Resistance Method is a process for conditioning of the electric current to subject it to manipulated resistance levels to cause a effect on the solution or substance as the conditioned current passes through
 3. These steps can be administered in any combination or simultaneously
 4. The Resistance Method utilizes the necessary computer hardware, and peripherals to simultaneously measure and manipulate the steps of the method to assist in processes necessary in the conditioning of the electric current. An example of this system is shown in
 5. (canceled)
 6. The Resistance Method utilizes a computer program to simultaneously measure and manipulate the variables of the process to assist in the conditioning of the electric current to subject it to the desired resistance levels to effect the substance as the current passes through
 7. (canceled)
 8. The reactor that this method uses can be of any size or shape as long as it's suitable to manipulate the variables of this method.
 9. The anode and cathode placement and number utilize spark gapping to aid in the manipulation of voltage and frequency to desired levels as it travels through the solution or substance.
 10. The manipulation of voltage in The Resistance Method assist in the transformation of the electric current to desired resistance levels as it travels through the solution or substance.
 11. The manipulation of the current frequency in The Resistance Method assist in the conditioning of the resistance of a substance to subject it to the conditioned current to effect the substance as the current passes through the solution or substance.
 12. The manipulation of amperage in The Resistance Method assist in the transformation of the electric current to desired resistance levels as it travels through the substance.
 13. The manipulation of ph in The Resistance Method assist in the conditioning of the resistance of a substance to subject it to the conditioned current to effect the substance as the current passes through.
 14. The manipulation of salinity assist in the conditioning of the resistance of a substance to subject it to the conditioned current to effect the substance as the current passes through.
 15. The manipulation of temperature in The Resistance Method assist in the conditioning of the resistance of a substance to subject it to the conditioned current to effect the substance as the current passes through.
 16. (canceled)
 17. The manipulation of atmospheric pressure in The Resistance Method assist in the conditioning of the electric current to subject it to the desired resistance levels to effect the substance as the current passes through.
 18. (canceled)
 19. The wiring of the reactor in series to one another assist in the conditioning of the electric current to subject it to the desired resistance levels to effect the substance as the current passes through.
 20. (canceled)
 21. (canceled) 